Data center cooling device

ABSTRACT

An apparatus for routing air passing through a vent of an enclosure with electrical equipment includes a routing portion, a channeling portion, and a distal portion. The routing portion deflects the air passing through the vent of the enclosure. The channeling portion forms a passage of the air between the routing portion and the distal portion. The distal portion allows the air to flow from the channeling portion to surrounding or from the surrounding to the channeling portion.

BACKGROUND

Heat dissipated by electronic equipment can be critical to operation ofthe equipment because it can have adverse effects on the performance andreliability of the equipment. One environment where heat control iscritical is a data center containing racks or cabinets of electronicequipment, such as servers, CPUs, storage, networking and communicationsystems.

To address the heat generated by electronic equipment in data centers,air cooling devices are used to provide a flow of cold air to theelectronic equipment. Such cooling devices are typically referred to ascomputer room air conditioning (CRAC) units. The CRAC units providecooler air into the data center, and the racks of electronic equipmentare cooled as the cooler air is drawn into the racks and over theequipment therein. The air passing over the equipment is heated by theoperating equipment and exhausted out of the racks, and returns to theCRAC units.

SUMMARY

In general terms, this disclosure is directed to an air conditioningsystem for a data center. In one possible configuration and bynon-limiting example, the air conditioning system includes a routingapparatus. Various aspects are described in this disclosure, whichinclude, but are not limited to, the following aspects.

One aspect is an apparatus for routing air passing through a vent of anenclosure with electrical equipment, the air flowing in a firstdirection at the vent of the enclosure, the apparatus comprising: arouting portion engaged with the enclosure and being in fluidcommunication with the vent of the enclosure, the routing portion beingconfigured to deflect the air passing through the vent of the enclosurein a second direction, the second direction being different from thefirst direction; a channeling portion being in fluid communication withthe routing portion and forming a passage of the air in the seconddirection; and a distal portion being in fluid communication with thechanneling portion and open to surroundings, the distal portionconfigured to allow the air to flow from the channeling portion to thesurroundings or from the surrounding to the channeling portion.

Another aspect is an air conditioning system for data center hardware,the system comprising: an enclosure with electrical equipment, theenclosure having a first vent and a second vent at a first side thereof,wherein the first vent is configured to allow air at a first temperatureto flow in a first direction between the enclosure and a surroundingtherethrough, and the second vent is configured to allow the air at asecond temperature to flow in a second direction between the enclosureand the surrounding therethrough, the second temperature being differentfrom the first temperature and the second direction opposite to thefirst direction, and a routing device configured to route the air at thefirst temperature between the first vent and surroundings, the routingdevice comprising: a routing portion engaged with the enclosure andbeing in fluid communication with the first vent of the enclosure, therouting portion configured to deflect the air at the first temperaturepassing through the first vent in a third direction, the third directiondifferent from the first direction; a channeling portion being in fluidcommunication with the routing portion and forming a passage for the airat the first temperature in the third direction; and a distal portionbeing in fluid communication with the channeling portion and open to thesurroundings, the distal portion configured to allow the air at thefirst temperature to flow between the channeling portion and thesurroundings, the surroundings adjacent a second side of the enclosure,the second side being different from the first side of enclosure.

A yet another aspect is a method of air conditioning for an enclosurewith electrical equipment, the method comprising: supplying air at afirst temperature to a first side of the enclosure, wherein theenclosure includes a first vent and a second vent, the first and secondvents arranged on the first side; receiving, by the enclosure, the airat the first temperature through the first vent of the enclosure;discharging, by the enclosure, air at a second temperature through thesecond vent of the enclosure, the second temperature higher than thefirst temperature; deflecting, by a routing device, the air at thesecond temperature to flow along a second side of the enclosure toward athird side of the enclosure, wherein the second side is adjacent thefirst side and the third side is opposite to the first side and adjacentthe second side; and discharging, by the routing device, the air at thesecond temperature to surroundings adjacent the third side of theenclosure.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic view of an example cooling system for a datacenter.

FIG. 2 is a front perspective view of an example electronic equipmentrack.

FIG. 3 is a rear perspective view of the electronic equipment rack ofFIG. 2.

FIG. 4 is a perspective view of an example routing apparatus installedto the equipment rack of FIGS. 2 and 3.

FIG. 5 is a schematic, side cross-sectional view of the routingapparatus installed to the equipment rack of FIG. 4.

FIG. 6 is a perspective view of an example routing apparatus.

FIG. 7 is a perspective view of an example deflecting portion of therouting apparatus of FIG. 6.

FIG. 8 is a front view of the deflecting portion of FIG. 7.

FIG. 9 is a schematic view of the routing apparatus of FIG. 6 with thechanneling portion extended.

DETAILED DESCRIPTION

Various embodiments will be described in detail with reference to thedrawings, wherein like reference numerals represent like parts andassemblies throughout the several views. Reference to variousembodiments does not limit the scope of the claims attached hereto.Additionally, any examples set forth in this specification are notintended to be limiting and merely set forth some of the many possibleembodiments for the appended claims.

FIG. 1 is a schematic view of an example cooling system 10 for a datacenter 12. The data center 12 includes a plurality of electronicequipment racks (also referred to herein as “cabinet(s)” or“enclosure(s)”) 14. The equipment racks 14 contain electronic equipment,such as servers, CPUs, storage, networking and communication systems. Insome embodiments, the equipment racks 14 are high-density racks in whichseveral pieces of electronic equipment are clustered together in theracks. In such cases, the equipment racks 14 can be preferably spacedapart across the entire floor area to alleviate the ineffectiveness ofcooling. An example of the equipment rack 14 is described in furtherdetail with reference to FIGS. 2 and 3.

The cooling system 10 operates to provide the data center withappropriate cooling to achieve optimum performance of electronicequipment in the data center. The cooling system 10 includes computerroom air conditioning (CRAC) units 16, cold aisles 18A, 18B and 18C(collectively, 18), hot aisles 20A and 20B (collectively, 20), and acold air circulation mechanism 22.

The CRAC units 16 operate to monitor and maintain the temperature, airdistribution and humidity in the data center 12. The CRAC units 16supply cold air into the data center 12. In some embodiments, the CRACunits 16 introduce cold air into the cold aisles 18 so that the cold airis drawn in the equipment racks 14. The air drawn in the racks 14 isheated by the electronic equipment therein and exhausted out of theracks 14. In some embodiments, the heated air is discharged into the hotaisles 20. The CRAC units 16 then intake the heated air collected at thehot aisles 20, for example.

The cold aisles 18 are configured to collect cold air generated by theCRAC units 16 so that the cold air is effectively drawn into theequipment racks 14. In some embodiments, the cold aisles 18 face outputducts of the CRAC units 16.

The hot aisles 20 provide passages for air that has been heated in theequipment racks 14 and exhausted therefrom before the heated air returnsto the CRAC units 16. In some embodiments, the hot aisles 20 are rowsinto which the heated air from the CRAC units pours.

In some embodiments, the cold aisles 18 are isolated from the hot aisles20 to prevent cold air and hot exhaust air from mixing each other. Asillustrated in FIG. 1, the cooling system 10 implements a hot aisle/coldaisle arrangement. In the hot aisle/cold aisle arrangement, the coolingsystem 10 lines up the electronic equipment racks 14 in alternating rowswith the cold aisles 18 and the hot aisles 20. As such, the cold aisles18 and the hot aisles 20 are separated with the rows of the racks 14therebetween.

In some embodiments, the cooling system 10 includes the cold aircirculation mechanism 22. The cold air circulation mechanism 22 operatesto take cold air from the CRAC units 16 and deliver the air to the coldaisles 18 so that the air is effectively drawn in the equipment racks14. The cold air circulation mechanism 22 includes a raised floor 24, aplenum 26, and vented floor tiles 28.

The raised floor 24 provides space for the equipment racks 14 and theCRAC units 16 to be arranged thereon. The raised floor 24 also definesthe cold aisles 18 and the hot aisles 20.

The plenum 26 is defined by the raised floor 24 and operates to providea path for the cold air to travel from the CRAC units to the ventedfloor tiles 28. The CRAC units 16 are in fluid communication with theplenum 26 through the raised floor 24 so that the CRAC units 16 providecold air into the plenum 26. The plenum 26 allows cold air to flow tothe cold aisles 18 through the vented floor tiles 28.

The vented floor tiles 28 are formed on the raised floor 24. In someembodiments, the vented floor tiles 28 are arranged along the coldaisles 18 to effectively deliver the cold air to the cold aisles 18only. Furthermore, the vented floor tiles 28 can be located adjacent theintake vents of the equipment racks 14 so that the cold air from theCRAC units 16 are delivered as closely as possible to the intake ventsof the equipment racks 14.

Some electronic equipment racks 14 are designed to draw cold air in atone side and exhaust warm air at another side of the rack. For example,each of the equipment racks 14 may have an intake vent at a front sideof the rack 14, which draws cold air therein, and an exhaust vent at arear side of the rack 14, which discharges heated air out of the rack14. The equipment racks 14 can be oriented so that the front sides faceeach other with the cold aisles 18 and the rear sides face each otherwith the hot aisles 20. In this manner, the cold air from the CRAC units16 can be separated from the hot air exhausted from the equipment racks14, thereby preventing the cold air from mixing with the hot air in thedata center 12.

In contrast, many electronic equipment racks 14 have the intake ventsfor drawing cold air in and the exhaust vents for discharging heated airat the same side of the racks. When such equipment racks 14 are arrangedfor the intake and exhaust vents to face the cold aisles 18, the heatedair from the equipment racks 14 is discharged to the cold aisles 18,instead of the hot aisles 20. When the racks 14 are arranged to face thehot aisles 20, the cold air provided from the CRAC units 16 has to passthrough the hot aisles 20 before it is drawn into the racks 14. In bothcases, cold air and hot exhaust air are mixed up at either the coldaisles 18 or the hot aisles 20. This prevents the effective coolingperformance of the cooling system 10 for the data center 12. An exampleof the electronic equipment rack having the intake vents and the exhaustvents at the same side is illustrated below with reference to FIGS. 2and 3.

FIG. 2 is a front perspective view of an example electronic equipmentrack 14. The electronic equipment rack 14 includes electronic equipment,such as servers, CPUs, storage, networking and communication systems. Inthe example of FIG. 2, the equipment rack 14 is designed for computernetwork switches. Examples of such computer network switches includeCisco MDS 9500 series, such as Cisco 9513 MDS Multilayer Director, whichis distributed by Cisco Systems, Inc. of Rosemont, Ill. The equipmentrack 14 includes a chassis 30, switching modules 32, and a fan tray 34.

The chassis 30 is designed to retain the switching modules 32, the fantray 34 and other electronic devices. The chassis 30 has a front panel36, a rear panel 38 (FIG. 3), a top panel 40, a bottom panel 42, andopposing side panels 44. The top panel 40, the bottom panel 42, and theopposing side panels 44 define an enclosure to accommodate the switchingmodules 32, the fan tray 34 and other electronic devices, such as powersupplies. The front panel 36 provides a plurality of slots 46 for theswitching modules 32 and the fan tray 34.

The switching modules 32 are configured to provide multiple switches forcomputer networking. In some embodiments, the switching modules 32 areconfigured as multilayer switches. The switching modules 32 are mountedinto the slots 46 arranged on the front panel 36.

The equipment rack 14 optionally includes the fan tray 34. The fan tray34 is configured to support at least one individual fan for circulatingair within the chassis 30. In this example, the fan tray 34 isvertically mounted into the chassis 30 adjacent one of the opposing sidepanels 44.

FIG. 3 is a rear perspective view of the electronic equipment rack 14 ofFIG. 2. The rear panel 38 of the chassis 30 includes a plurality ofslots 48, an intake vent 50, and an exhaust vent 52.

The slots 48 are configured to accommodate electronic devices within thechassis 30. Such electronic devices include power supplies andfunctional modules.

The intake vent 50 operates to draw cold air in the chassis 30. Theintake vent 50 is configured to receive cold air provided by the CRACunits 16 and delivered by the cooling system 10. In this example, theintake vent 50 is arranged at a lower portion of the rear panel 38.

The exhaust vent 52 operates to exhaust air out of the chassis 30. Inthis example, the exhaust vent 52 is arranged at an upper portion of therear panel 38. When the cold air is drawn in the equipment rack 14through the intake vent 50, the air flows around the electronicequipment within the rack 14. Heat generated by the electronic equipmentis transferred to the air, thereby increasing the temperature of theair. The heated air then tends to rise up for lower density than thecold air and reaches the exhaust vent 52 located at the upper portion ofthe rear panel 38. The heated air is exhausted out of the equipment rack14 and eventually returns to the CRAC units 16.

The cooling system 10 as described with reference to FIG. 1 may notperform optimally with the equipment racks 14 of FIGS. 2 and 3 becausecold air and hot exhaust air can be mixed at a rear side of the rack 14,which is adjacent the rear panel 38 of the rack 14. As explained above,if the equipment racks 14 are arranged for the rear panels 38 to facethe cold aisles 18, the heated air from the equipment racks 14 isdischarged to the cold aisles 18 and increases the temperature of thecold aisles 18, thereby impairing the cooling effect of the cold airsupplied by the CRAC units 16. Similarly, if the rear panels 38 isarranged to face the hot aisles 20, cold air meets hot exhaust air atthe hot aisles 20 before being drawn into the intake vent 50 of theequipment rack 14. Therefore, the cooling system 10 will provide betterperformance with a routing apparatus for either conveying cold air fromthe cold aisles 18 to the intake vent 50 or delivering hot exhaust airfrom the exhaust vent 52 to the hot aisles 20. An example of a routingapparatus adapted for the equipment rack 14 or the chassis 30 of FIGS. 2and 3 is illustrated with reference to FIGS. 4-9.

FIG. 4 is a perspective view of an example routing apparatus 60installed to the equipment rack 14 of FIGS. 2 and 3. In this example,the rear panel 38 of the chassis 30 is arranged to face the hot aisle20. Thus, both of the intake vent 50 and the exhaust vent 52 open towardthe hot aisle 20. As shown in FIG. 4, the intake vent 50 is covered bythe routing apparatus 60, which defines a passage between the intakevent 50 and the cold aisle 18, at which the front panel 36 of thechassis 30 is arranged. The routing apparatus 60 operates to block theintake vent 50 from the hot aisle 20 and prevent hot air discharged fromthe exhaust vent 52 from mixing with cold air supplied by the CRAC units16. Furthermore, the routing apparatus 60 forms a conduit or passagefrom the cold aisle 18 to the intake vent 50 so that cold air suppliedby the CRAC units 16 is effectively drawn into the intake vent 50 whilebeing isolated from the hot exhaust air at the hot aisle 20.

FIG. 5 is a schematic, side cross-sectional view of the routingapparatus 60 installed to the equipment rack 14 of FIG. 4. The routingapparatus 60 is installed to the equipment rack 14 to form an isolatedconduit from the cold aisle 18 to the intake vent 50 of the chassis 30.In some embodiments, the routing apparatus 60 includes a routing portion62, a channeling portion 64, and a distal portion 66.

The routing portion 62 operates to deflect airflow between the intakevent 50 and the channeling portion 64. The routing portion 62 isdesigned to engage a lower portion of the rear panel 38 and cover theintake vent 50. By covering the intake vent 50, cold air drawn into theintake vent 50 can be isolated from hot air exhausted from the exhaustvent 52 at the same side of the equipment rack 14. Further, the routingportion 62 is in fluid communication with the channeling portion 64.

The channeling portion 64 operates to provide a passage 68 for airbetween the routing portion 62 and the distal portion 66. In thisexample, the channeling portion 64 is arranged to engage the bottompanel 42 of the chassis 30 and forms the passage 68 for cold air fromthe distal portion 66 to the routing portion 62 along the channelingportion 64. The cold air is conveyed along the channeling portion 64 ina direction (d1) generally parallel with the bottom panel 42 of thechassis 30.

The distal portion 66 operates to allow air to flow from surrounding tothe channeling portion 64, or vice versa. The distal portion 66 is influid communication with the channeling portion 64. In this example, thedistal portion 66 opens to surrounding at the cold aisle 18. Thus, thedistal portion 66 draws cold air from the cold aisle 18 and delivers itto the channeling portion 64.

In this example, as the rear panel 38 of the chassis 30 faces the hotaisle 20 and the front panel 36 faces the cold aisle 18, the routingapparatus 60 operates to draw cold air from the cold aisle 18 into theintake vent 50 of the chassis 30. As illustrated in FIG. 5, the distalportion 66 is arranged adjacent the front panel 36 of the chassis 30 andopens to surrounding at the cold aisle 18. Thus, the distal portion 66draws cold air from the cold aisle 18 and allows the cold air to flowinto the channeling portion 64. Then, the cold air flows along thepassage 68 defined by the channeling portion 64. The direction (d1) ofthe cold air flowing along the passage 68 is generally parallel with thebottom panel 42 of the chassis 30.

When the cold air reaches the routing portion 62, the cold air isdeflected by the routing portion 62 to the intake vent 50. Inparticular, the routing portion 62 changes the direction of the cold airand guide the cold air into the intake vent 50 of the chassis 30. Thus,the direction (d1) of the cold air flowing along the channeling portion64 is substantially opposite to a direction (d2) of the cold air passingthrough the intake vent 50.

Although it has been described or illustrated that the routing apparatus60 is installed to the equipment rack 14 to cover the intake vent 50,the routing apparatus 60 can also be installed to the equipment rack 14to cover the exhaust vent 52 if the rear panel 38 of the chassis 30 isarranged to face the cold aisle 18. In this case, the routing apparatus60 operates to convey hot air exhausted from the exhaust vent 52 to thehot aisle 20 and isolate the hot exhaust air from cold air at the coldaisle 18. In particular, the routing portion 62 will engage an upperportion of the rear panel 38 to cover the exhaust vent 52. Thechanneling portion 64 engages the top panel 40 of the chassis 30 andforms a passage for hot exhaust air from the routing portion 62 to thedistal portion 66 along the channeling portion 64. The distal portion 66is arranged to open to surrounding at the hot aisle 20. Thus, the distalportion 66 discharges hot exhaust air conveyed from the exhaust vent 52to the surrounding at the hot aisle 20.

FIGS. 6-9 illustrate an example routing apparatus 60 adapted for theadapted for the equipment rack 14 of FIGS. 2 and 3. In this example, therouting apparatus 60 is primarily described hereinafter as beingassociated with the intake vent 50 of the chassis 30 to route cold airfrom the cold aisle 18 to the intake vent 50. As discussed above,however, the routing apparatus 60 can also be installed to the exhaustvent 52 of the chassis 30 for conveying hot exhaust air to the hot aisle20. As the same principles and features apply to both of theconfigurations, the description of the routing apparatus 60 coupled tothe exhaust vent 52 is omitted for brevity purposes.

FIG. 6 is a perspective view of an example routing apparatus 60. Asdiscussed above with reference to FIG. 5, the routing apparatus 60includes the routing portion 62, the channeling portion 64, and thedistal portion 66.

The routing portion 62 includes a coupling portion 72, a deflectingportion 74, a channel-matching portion 76, and proximal installationflanges 94.

The coupling portion 72 is engaged with the rear panel 38 of the chassis30 to cover the intake vent 50 or the exhaust vent 52. In the examplesof FIGS. 4 and 5, the coupling portion 72 is arranged to cover theintake vent 50 of the chassis 30. In some embodiments, the couplingportion 72 is dimensioned to cover a portion of the rear panel 38 of thechassis 30 that includes the intake vent 50. In other embodiments, thecoupling portion 72 is dimensioned to cover the entire width of the rearpanel 38 while covering the intake vent 50. For example, the couplingportion 72 has a width (W1) and a height (H1). The width (W1) of thecoupling portion 72 is substantially sized the same as width of the rearpanel 38 of the chassis 30 so that the coupling portion 72 covers theentire width of the rear panel 38 that includes the intake vent 50.Alternatively, the width (W1) of the coupling portion 72 is sized tomeet a width of the intake vent 50. The height (H1) of the couplingportion 72 is determined to cover the entire height of the intake vent50.

The deflecting portion 74 is configured to effectively change thedirection of air flowing from the channeling portion 64 toward theintake vent 50. The deflecting portion 74 is described in further detailwith reference to FIGS. 7 and 8.

The channel-matching portion 76 is configured to couple the routingportion 62 to the channeling portion 64 and maintain a fluidcommunication between the routing portion 62 and the channeling portion64. In some embodiments, the channel-matching portion 76 has a width(W2) and a height (H2), which are substantially the same as a width (Wc)and a height (Hc) of the channeling portion 64, respectively.

The proximal installation flanges 94 are configured to couple therouting portion 62 to the equipment rack 14 and/or the chassis 30. Insome embodiments, the flanges 94 are arranged adjacent thechannel-matching portion 76 and extend outwardly from the opposing sidesof the channel-matching portion 76. The flanges 94 of the routingportion 62 are attached to a predetermined location of the equipmentrack 14 and/or the chassis 30, which can provide adequate support forthe routing portion 62. For example, the flanges 94 can be attached tothe rear panel 38 of the chassis 30 or the side panels 44 of the chassis30. In some embodiments, the flanges 94 are attached to the equipmentrack 14 and/or the chassis 30 with fasteners of any type. In otherembodiments, the flanges 94 are soldered to the equipment rack 14 and/orthe chassis 30 for support of the routing portion 62.

The routing apparatus 60 also includes the channeling portion 64. Thechanneling portion 64 has a first end 82 and a second end 84, andprovides the passage 68 between the first and second ends 82 and 84. Thechanneling portion 64 is coupled to the channel-matching portion 76 ofthe routing portion 62 at the first end 82. The channeling portion 64 isin fluid communication with the distal portion 66 at the second end 84.

The channeling portion 64 has opposing side panels 86 and 88 and a crosspanel 90. The cross panel 90 extends between the opposing side panels 86and 88. In some embodiments, the opposing side panels 86 and 88 aresubstantially perpendicular to the cross panel 90. The opposing sidepanels 86 an 88 and the cross panel 90 extends between the first end 82and the second end 84. In this example, the opposing side panels 86 and88 are arranged to be engaged with the bottom panel 42 of the chassis 30while the cross panel 90 is substantially parallel to the bottom panel42. As such, the opposing side panels 86 and 88, the cross panel 90, andthe bottom panel 42 of the chassis 30 cooperate to form the enclosedpassage 68 with four-sided boundary. In other embodiments, thechanneling portion 64 has an opposing cross panel adjacent the opposingside panels 86 and 88 and parallel to the cross panel 90 to form theenclosed passage 68 without the bottom panel 42 of the chassis 30.

The channeling portion 64 has the width (Wc) (that is, the width of),the height (Hc) and a length (Lc). The width (Wc) of the channelingportion 64 is defined by the width of the cross panel 90. The height(Hc) of the channeling portion 64 is defined by the height of the sidepanel 86 or 88. In some embodiments, the height (Hc) is substantiallythe same as the height (H2) of the channel-matching portion 76. Thewidth (Wc) is substantially the same as the width (W2) of thechannel-matching portion 76. In some embodiments, the width (Wc) isconfigured to be shorter than a width of the bottom panel 42 of thechassis 30 so that the channeling portion 64 and the bottom panel 42cooperate to form the passage 68. In other embodiments, the width (Wc)is substantially the same as the width of the bottom panel 42 of thechassis 30. For example, the width (Wc) can be about 19 inches and theheight (Hc) can be about 3.5 inches.

The length (Lc) of the channeling portion 64 is defined by the length ofthe side panel 86 or 88 and/or the cross panel 90 from the first end 82to the second end 84. In some embodiments, the length (Lc) isdimensioned to allow the distal portion 66 to be arranged adjacent thecold aisle 18 so that cold air is effectively drawn to the channelingportion 64 through the distal portion 66. For example, the length (Lc)is sized to be substantially the same as a length or depth of the bottompanel 42 of the chassis 30, which is a distance between the front panel36 and the rear panel 38 along the bottom panel 42. Furthermore, thelength (Lc) is adjustable as necessary, which is described in furtherdetail with reference to FIG. 9.

The routing apparatus 60 further includes the distal portion 66. Thedistal portion 66 is exposed to surrounding at the cold aisle 18 to drawcold air from the cold aisle 18 into the passage 68 of the channelingportion 64. The distal portion 66 is arranged at the second end 84 ofthe channeling portion 64 and in fluid communication with the channelingportion 64. In this example, the distal portion 66 is integrally madewith the channeling portion 64. In other embodiments, the distal portion66 is a separate component that is coupled to the second end 84 of thechanneling portion 64.

In some embodiments, the distal portion 66 includes distal installationflanges 96 for coupling the distal portion 66 to the equipment rack 14and/or the chassis 30. In some embodiments, the distal installationflanges 96 are arranged adjacent the second end 84 of the channelingportion 64 and extend outwardly from the opposing sides of the distalportion 66. Similarly to the proximal installation flanges 94, thedistal installation flanges 96 are attached to a predetermined locationof the equipment rack 14 and/or the chassis 30, which can provideadequate support for the distal portion 66. For example, the flanges 96can be attached to the front panel 36 of the chassis 30 or the sidepanels 44 of the chassis 30. In some embodiments, the flanges 96 areattached to the equipment rack 14 and/or the chassis 30 with fastenersof any type. In other embodiments, the flanges 96 are soldered to theequipment rack 14 and/or the chassis 30 for support of the distalportion 66. As such, the distal installation flanges 96 and the proximalinstallation flanges 94 cooperate to couple the routing apparatus 60 tothe equipment rack 14 and/or the chassis 30 so that the equipment rack14 and/or the chassis 30 support the routing apparatus 60.

In this example, the dimension of the distal portion 66 is substantiallythe same as the dimension of the channeling portion 64. However, thedistal portion 66 can have a different size (for example, width and/orheight) from the channeling portion 64. In other embodiments, the distalportion 66 can have one or more curved or deflected portions that guidethe opening of the distal portion 66 in a predetermined direction.

In some embodiments, the routing apparatus 60 is made from aluminum forconvenient fabrication and easy fit on the equipment rack 14. In otherembodiments, the routing apparatus 60 is made from a material with highinsulating capability in order to effectively isolate cold air from hotair, or vice versa.

FIGS. 7 and 8 illustrate the deflecting portion 74 of the routingportion 62 of FIG. 6. FIG. 7 is a perspective view of an exampledeflecting portion 74. FIG. 8 is a front view of the deflecting portion74 of FIG. 7. The deflecting portion 74 of the routing portion 62operates to deflect airflow from the channeling portion 64 to the intakevent 50. In this example, as air flowing along the channeling portion 64has the direction (d1) substantially opposite to the direction (d2) ofair passing through the intake vent 50, the deflecting portion 74 isconfigured to change the direction of cold air substantially 180 degreefrom the channeling portion 64 to the intake vent 50. In someembodiments, the deflecting portion 74 includes a first bent portion102, an intermediate portion 104, and a second bent portion 106.

The first bent portion 102 is connected to the coupling portion 72 andin fluid communication with the intake vent 50. The first bent portion102 is also connected to the intermediate portion 104 so that the intakevent 50 is in fluid communication with the intermediate portion 104. Inthis example, the first bent portion 102 has the same width (W1) as thecoupling portion 72. The first bent portion 102 is configured to form anangled portion between the coupling portion 72 and the intermediateportion 104 so that cold air flows along the angled portion from theintermediate portion 104 to the intake vent 50. In some embodiments, anangle (A1) of the first bent portion 102 is about 45 degree with respectto a surface parallel to the direction (d1) or the passage 68 of thechanneling portion 64. In other embodiments, the angle (A1) of the firstbent portion 102 can range between 20 and 80 degrees, depending onseveral factors, including, but not limited to, a relative geometry ofassociated portions such as the dimensions of the first bent portion102, the intermediate portion 104 and the second bent portion 106. Inother embodiments, the first bent portion 102 is configured to have acurved portion having a predetermined curvature, which connects thecoupling portion 72 and the intermediate portion 104.

The intermediate portion 104 connects the first bent portion 102 and thesecond bent portion 106 and allows airflow to transition between thefirst bent portion 102 and the second bent portion 106. In someembodiments, the intermediate portion 104 is substantially perpendicularto the direction (d1) or the passage 68 of the channeling portion 64. Inthis example, the intermediate portion 104 has the same width (W1) asthe first bent portion 102 at the upper part thereof and the same width(W2) as the second bent portion 106 in order to match the difference inwidth between the first bent portion 102 and the second bent portion106.

The second bent portion 106 is connected to the channel-matching portion76 and in fluid communication with the channeling portion 64. The secondbent portion 106 is also connected to the intermediate portion 104 sothat the channeling portion 64 is in fluid communication with theintermediate portion 104. In this example, the second bent portion 106has the same width (W2) as the channel-matching portion 76. The secondbent portion 106 is configured to form an angled portion between theintermediate portion 104 and the channel-matching portion 76 so thatcold air flows along the angled portion from the channeling portion 64to the intermediate portion 104. Subsequently, the cold air flows alongthe first bent portion 102 toward the intake vent 50. In someembodiments, an angle (A2) of the second bent portion 106 is about 45degree with respect to a surface parallel to the direction (d1) or thepassage 68 of the channeling portion 64. In other embodiments, the angle(A2) of the second bent portion 106 can range between 20 and 80 degree,depending on several factors, including, but not limited to, a relativegeometry of associated portions such as the dimensions of the first bentportion 102, the intermediate portion 104 and the second bent portion106. In other embodiments, the second bent portion 106 is configured tohave a curved portion having a predetermined curvature, which connectsthe channel-matching portion 76 and the intermediate portion 104.

FIG. 9 is a schematic view of the routing apparatus 60 of FIG. 6 withthe channeling portion 64 extended. In some embodiments, the channelingportion 64 is adjustable in length (Lc). The length (Lc) of thechanneling portion 64 can be adjusted, depending on a length or depth ofthe bottom panel 42 between the front panel 36 and the rear panel 38 ofthe chassis 30. In other embodiments, the length (Lc) can be adjusted toarrange the distal portion 66 at a predetermined location with respectto the equipment rack 14 or the chassis 30. For example, if the distalportion 66 is to be arranged to protrude beyond the front panel 36 ofthe chassis at a predetermined distance, the channeling portion 64 canbe extended to have a greater length (Lc) than the depth of the bottompanel 42 between the front panel 36 and the rear panel 38 of the chassis30.

In some embodiments, the channeling portion 64 includes multiple sets ofthe opposing side panels 86 and 88 and the cross panel 90. In thisexample, the channeling portion 64 has two sets 118 and 128 of thepanels. A first set 118 includes first opposing side panels 112 and 114and a first cross panel 116. A second set 128 includes second opposingside panels 122 and 124 and a second cross panel 126. The first set 118is engaged with the second set 128. In the example of FIG. 9, the secondset 128 is accommodated within the first set 118. The second set 128 canslide on the first set 118 along the passage 68 of the channelingportion 64. In particular, the second opposing side panels 122 and 124are slideably engaged with the first opposing side panels 112 and 114,respectively, and the second cross panel 126 is slideably engaged withthe first cross panel 116. Therefore, the second opposing side panels122 and 124 and the second cross panel 126 can selectively be pulled outfrom, or pushed into, the first opposing side panels 112 and 114 and thefirst cross panel 116 (or vice versa) to set the length (Lc) of thechanneling portion 64.

The channeling portion 64 also includes a coupling device to connect thefirst set 118 and the second set 128. In some embodiments, the couplingdevice is a fastener, such as, but not limited to, bolts, clamps, clips,pins, latches, threaded fasteners, or other devices of any type. Inother embodiments, the first set 118 and the second set 128 are coupledwith slide rails, which can also provide slidable engagement between thefirst set 118 and the second set 128.

An additional embodiment is directed to a method of cooling theequipment racks 14 of FIGS. 2 and 3. In this embodiment, the rear panel38 of the chassis 30 is arranged to face the cold aisle 18 so that bothof the intake vent 50 and the exhaust vent 52 open toward the cold aisle18. The method includes steps of supplying cold air from the CRAC units16 to surrounding adjacent the rear panel 38 of the chassis 30;receiving, by the chassis 30, the cold air through the intake vent 50;after the cold air circulates within the equipment rack 14 and is heatedby electronic equipment within the rack 14, discharging, by the chassis30, the heated air through the exhaust vent 52; deflecting, by therouting apparatus 60 associated with the exhaust vent 52, the heated airto flow along the top panel 40 of the chassis 30 toward the front panel36 of the chassis 30; and discharging, by the routing apparatus 60, theheated air to surrounding adjacent the front panel 36 of the chassis 30at the hot aisle 20.

Yet another embodiment is directed to a method of cooling the equipmentracks 14 of FIGS. 2 and 3. In this embodiment, the rear panel 38 of thechassis 30 is arranged to face the hot aisle 20 so that both of theintake vent 50 and the exhaust vent 52 open toward the hot aisle 20. Themethod includes steps of supplying cold air from the CRAC units 16 tosurrounding adjacent the rear panel 38 of the chassis 30; receiving, bythe routing apparatus 60 associated with the intake vent 50, cold airfrom surrounding adjacent the front panel 36 of the chassis 30 at thecold aisle 18; deflecting, by the routing apparatus 60, the cold air toflow along the bottom panel 42 of the chassis 30 toward the front panel36 of the chassis 30; receiving, by the chassis 30, the cold air throughthe intake vent 50; and, after the cold air circulates within theequipment rack 14 and is heated by electronic equipment within the rack14, discharging, by the chassis 30, the heated air through the exhaustvent 52 of the chassis 30 to surrounding adjacent the rear panel 38 ofthe chassis 30 at the hot aisle 20.

The various embodiments described above are provided by way ofillustration only and should not be construed to limit the claimsattached hereto. For example, although the routing apparatus is hereindescribed to be used with equipment, it can also be applied to any typeof racks, cabinets or enclosures for the purpose of changing a directionof air flowing into, or from, the racks, cabinets or enclosures. Assuch, those skilled in the art will readily recognize variousmodifications and changes that may be made without following the exampleembodiments and applications illustrated and described herein, andwithout departing from the true spirit and scope of the followingclaims.

What is claimed is:
 1. An apparatus for routing air passing through avent of an enclosure with electrical equipment, the apparatuscomprising: a routing portion engaged with the enclosure and being influid communication with and covering the vent of the enclosure, thevent provided at a first side of the enclosure; a distal portionarranged at a second side of the enclosure and open to surroundings, thesecond side of the enclosure being opposite to the first side of theenclosure; and a channeling portion extending between a first end and asecond end and forming a passage of the air between the first end andthe second end, the channeling portion being in fluid communication withthe routing portion at the first end and in fluid communication with thedistal portion at the second end, wherein the distal portion, therouting portion, and the channeling portion are positioned to allow theair to flow from the electrical equipment to the vent to the routingportion to the channeling portion to the distal portion to thesurroundings or from the surroundings to the distal portion to thechanneling portion to the routing portion to the vent to the electricalequipment.
 2. The apparatus of claim 1, wherein the routing portion isengaged with the first side of the enclosure, and the channeling portionis engaged with the enclosure between the first side of the enclosureand the second side of the enclosure.
 3. The apparatus of claim 1,wherein the enclosure has a third side extending between the first sideand the second side, and the passage of the channeling portion issubstantially parallel with the third side of the enclosure.
 4. Theapparatus of claim 1, wherein the routing portion includes a couplingportion, a deflecting portion, and a channel-matching portion, whereinthe coupling portion is configured to engage the vent of the enclosureand dimensioned to match a size of the vent, wherein thechannel-matching portion is coupled to the channeling portion and influid communication with the channeling portion, and wherein thedeflecting portion includes a first bent portion, a second bent portionand an intermediate portion connecting the first bent portion to thesecond bent portion, the first bent portion connected to the couplingportion and configured to deflect the air flowing between the vent ofthe enclosure and the intermediate portion, and the second bent portionconnected to the channel-matching portion and configured to deflect theair flowing between the intermediate portion, and the channel-matchingportion.
 5. The apparatus of claim 1, wherein the electrical equipmentincludes data center hardware.
 6. An air conditioning system for datacenter hardware, the system comprising: an enclosure with electricalequipment, the enclosure having a first vent and a second vent at afirst side thereof, wherein the first vent is configured to allow air ata first temperature to flow in a first direction therethrough, and thesecond vent is configured to allow the air at a second temperature toflow in a second direction therethrough, the second temperature beingdifferent from the first temperature and the second direction oppositeto the first direction, and a first routing device configured to routethe air at the first temperature between the first vent andsurroundings, the first routing device comprising: a routing portionengaged with the enclosure and being in fluid communication with andcovering the first vent of the enclosure; a distal portion arranged at asecond side of the enclosure and open to the surroundings, the secondside of the enclosure being opposite to the first side of the enclosure;and a channeling portion extending between a first end and a second endand forming a passage of the air between the first end and the secondend, the channeling portion being in fluid communication with therouting portion at the first end and in fluid communication with thedistal portion at the second end, wherein the distal portion, therouting portion, and the channeling portion are positioned to allow theair to flow from the electrical equipment to the first vent to therouting portion to the channeling portion to the distal portion to thesurroundings or from the surroundings to the distal portion to thechanneling portion to the routing portion to the first vent to theelectrical equipment.
 7. The system of claim 6, further comprising: anair source providing the air at the first temperature, the firsttemperature lower than the second temperature, wherein the routingportion is engaged with the first side of the enclosure; wherein thechanneling portion is engaged with the enclosure between the first sideand the second side.
 8. The system of claim 6, wherein the enclosure hasa third side extending between the first side and the second side, andthe passage of the channeling portion is substantially parallel with thethird side of the enclosure.
 9. The system of claim 8, wherein the airat the first temperature is supplied to the second side of theenclosure, and wherein the distal portion is configured to receive theair at the first temperature therethrough and deliver the air at thefirst temperature to the routing portion through the channeling portion.10. The system of claim 6, further comprising: an air source providingthe air at the first temperature to the first vent of the enclosure, thefirst temperature being lower than the second temperature.
 11. Thesystem of claim 10, wherein the air at the first temperature is suppliedto the first side of the enclosure.
 12. The system of claim 6, whereinthe routing portion includes a coupling portion, a deflecting portion,and a channel-matching portion, wherein the coupling portion isconfigured to engage the first vent of the enclosure and dimensioned tomatch a size of the first vent, wherein the channel-matching portion iscoupled to the channeling portion and in fluid communication with thechanneling portion, and wherein the deflecting portion includes a firstbent portion, a second bent portion, and an intermediate portionconnecting the first bent portion to the second bent portion, the firstbent portion connected to the coupling portion and configured to deflectthe air flowing between the first vent of the enclosure and theintermediate portion, the second bent portion connected to thechannel-matching portion and configured to deflect the air flowingbetween the intermediate portion and the channel-matching portion.
 13. Amethod of air conditioning for an enclosure with electrical equipment,the method comprising: supplying air at a first temperature to a firstside of the enclosure, wherein the enclosure includes a first vent and asecond vent, the first and second vents arranged on the first side;receiving, by the enclosure, the air at the first temperature throughthe first vent of the enclosure in a first flow direction; discharging,by the enclosure, the air at a second temperature through the secondvent of the enclosure in a second flow direction, the second temperaturebeing higher than the first temperature, the second flow direction beingopposite the first flow direction; deflecting, by a routing device thatcovers the second vent, the air at the second temperature to flow alonga second side of the enclosure outside the enclosure toward a third sideof the enclosure, wherein the second side is adjacent the first side andthe third side is opposite to the first side and adjacent the secondside; and discharging, by the routing device, the air at the secondtemperature to surroundings adjacent the third side of the enclosure.14. The method of claim 13, further comprising: receiving, by therouting device, the air at a third temperature from the surroundingsadjacent the third side of the enclosure; channeling the air at thethird temperature to flow along the second side of the enclosure towardthe first side of the enclosure; deflecting, by the routing device, theair at the third temperature toward the second vent; receiving, by theenclosure, the air at the third temperature through the second vent ofthe enclosure; and discharging, by the enclosure, the air at a fourthtemperature through the first vent of the enclosure to the surroundingsadjacent the first side of the enclosure, the fourth temperature beinghigher than the third temperature.
 15. The method of claim 13, whereinthe routing device comprises: a routing portion engaged with theenclosure and being in fluid communication with the second vent of theenclosure; a distal portion arranged at the third side of the enclosureand open to surroundings; and a channeling portion extending between afirst end and a second end and forming a passage of the air between thefirst end and the second end, the channeling portion being in fluidcommunication with the routing portion at the first end and in fluidcommunication with the distal portion at the second end, wherein thedistal portion is configured to allow the air to flow from thechanneling portion to the surroundings or from the surroundings to thechanneling portion.